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FLUID DYNAMICS Made By: Prajapati Dharmesh Jyantibhai (140393106006)
GOVERNING EQUATIONS In Fluid Mechanics
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Fascinating fluids Fluid dynamics is the key to our understanding of some of the most important phenomena in our physical world: ocean currents and weather systems.
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The continuity assumption: Knudsen Number Governing equations
Continuum mechanics Modeling fluids Governing equations Conservation equations Constitutive equations Aerodynamics application Physics of flight and the Coanda effect
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Knudsen number Problems with Knudsen numbers at or above unity must be evaluated using statistical mechanics for reliable solutions
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The continuity assumption
The continuity assumption considers fluids to be continuos. That is, properties such as density, pressure, temperature, and velocity are taken to be well-defined at infinitely small points, and are assumed to vary continuously from one point to another. The discrete, molecular nature of a fluid is ignored density ρ(r,t) flow velocity u(r,t) pressure p(r,t) temperature T(r,t)
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The continuum method is generaly used to describe fluid dynamics
The vast majority of phenomena encoutered in fluid mechanics fall well within the continuum domain and may involve liquids as well as gases
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Modeling fluids Eulerian description: a fixed reference frame is employed relative to which a fluid is in motion; Time and spatial position in this reference frame, {t, r} are used as independent variables The fluid variables such as mass, density, pressure and flow velocity which describe the physical state of the fluid flow in question are dependent variables as they are functions of the independent variables
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Modeling fluids Lagrangian description the fluid is described in terms of its constituent fluid elements; Attention is fixed on a particular mass of fluid as it flows
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Modeling fluids Control volumes
The control volume is arbitrary in shape and each conservation principle is applied to an integral over the control volume
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Modeling fluids Reynold’s Transport Theorem:
Relates the lagrangian derivative of a volume integral of a given mass to a volume integral in which the integrand has eulerian derivatives only
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Governing equations The governing equations consist of conservation equations and constitutive equations; conservation equations apply whatever the material studied; constitutive equations depend from the material;
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Governing equations Conservation equations
Conservation of mass-Continuity equation: Continuity equation for an incompressible fluid:
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Governing equations Conservation equations
Conservation of momentum The principle of conservation of momentum is in fact an application of Newton’s second law of motion to an element of fluid
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Governing equations Conservation equations
Conservation of energy the modified form of the first law of thermodynamics applied to an element of fluid states that the rate of change in the total energy (intrinsic plus kinetic) of the fluid as it flows is equal to the sum of the rate at which work is being done on the fluid by external forces and the rate on which heat is being added by conduction
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Constitutive equations
The nine elements of the stress tensor have been expressed in terms of the pressure and the velocity gradients and two coefficients and . These coefficients cannot be determined analytically and must be determined empirically. They are the viscosity coefficients of the fluid. The second constitutive relation is Fourier’s Law for heat conduction
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Navier-Stokes Equations
The equation of momentum conservation together with the constitutive relation for a Newtonian fluid yield the famous Navier-Stokes equations, which are the principal conditions to be satisfied by a fluid as it flows
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Navier-Stokes Equations
The central equations for fluid dynamics are the Navier-Stokes equations, which are non-linear differential equations that describe the flow of a fluid whose stress depends linearly on velocity and on pressure. The unsimplified equations do not have a general closed-form solution, so they are only of use in computational fluid dynamics. The equations can be simplified in a number of ways. All of the simplifications make the equations easier to solve. Some of them allow appropriate fluid dynamics problems to be solved in closed form
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Navier-Stokes Equations
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"That we have written an equation does not remove from the flow of fluids its charm or mystery or its surprise." --Richard Feynman [1964] Coanda Effect
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